RU2091095C1 - Method for removal of carbon dioxide from air in manned section of object of collective protection - Google Patents

Abstract

FIELD: recovery of air in hermetically closed rooms. SUBSTANCE: method involves chemical binding of carbon dioxide with alkali solution of elements of second group in absorber in the presence of catalyst, such as solid particles of carbonates; positioning metallized burden, for instance copper chips, above solution surface; depositing drops of alkali solution bubbled with air to bind carbon dioxide failed to react in alkali solution; drying and cooling oxygen-enriched air. EFFECT: increased efficiency in cleaning air in closed objects of collective protection, improved optimum conditions for men working in these objects without deterioration of physical factors of habitat. 2 cl

Description

 The invention relates to methods for purifying indoor air, and in particular to methods for regenerating air in hermetically sealed collective protection facilities, by restoring the physical and chemical composition of air in an inhabited compartment with a long-term shelter of personnel.

Known methods based on improving the physical composition of the air in the room by cooling and drying the air before being fed into the habitable compartment [1]
There is also known a method of air regeneration in an inhabited compartment of an object of collective defense [2]. It provides the restoration and maintenance of the necessary composition of air for oxygen breathing in oxygen O ₂ and carbon dioxide CO ₂ in inhabited compartments of military shelters.

Обе реакции протекают на границах твердой и газообразной фаз и являются экзотермическими. Это, с одной стороны, способствует возникновению естественной конвекции регенерируемого воздуха, а с другой, увеличивает теплоизбытки (от 50 до 150 ккал/ч) и повышает влажность в обитаемом отсеке объекта коллективной защиты.The method is based on the use of a plate of an oxygen-containing substance for air regeneration, which includes elements of the first group (potassium peroxide KO ₂ or sodium NaO ₂ ). The substance of the regenerative plates, which has strong alkaline and oxidizing properties, enters into a chemical reaction with carbon dioxide and water vapor in the regenerated air, as a result of which oxygen is released from the plates:

Both reactions proceed at the boundaries of solid and gaseous phases and are exothermic. This, on the one hand, contributes to the occurrence of natural convection of the regenerated air, and on the other hand, increases the heat surplus (from 50 to 150 kcal / h) and increases the humidity in the inhabited compartment of the collective protection facility.

The disadvantages of the known method of air regeneration are:
deterioration of the temperature and humidity regime during the air regeneration in the inhabited compartment of the collective defense facility (temperature rises to 50-80 ^o C, and humidity 65-75%), while the sheltering personnel begin to feel stuffy, their health worsens;
decrease in the working capacity of personnel due to uncomfortable conditions;
a hard crust of carbonate (K ₂ CO ₃ or Na ₂ CO ₃ ) forms on the reactive surface of the regenerative substance, which inhibits the reaction and leads to incomplete use (only 80%) of the starting material;
the time of regenerative action is limited, and the shelf life of the regenerative substance is also limited (it has strong alkaline and oxidizing properties, therefore it requires periodic replacement);
the regenerative substance used is explosive and fire hazard, which entails additional costs to ensure the safety of its storage and operation.

The closest analogue in technical essence to the proposed method of air regeneration is a method of purifying air from carbon dioxide, implemented in a closed-air atmosphere regeneration system [3]
This method consists in the fact that carbon dioxide CO _{2 is} bound by an alkaline solution of the elements of the first group in a heterogeneous gas-liquid medium. The carbon dioxide binding process is carried out as follows: an alkaline solution of the elements of the first group is pumped into the absorber and air with a high content of CO ₂ is pumped through it. In this case, a heterogeneous gas-liquid medium is created, and in the absorber reactions occur between the constantly supplied alkali and carbon dioxide, as a result of which oxygen O _{2 is released} .

However, this method of purifying air from carbon dioxide (and the system for regenerating the atmosphere in an enclosed space that implements it) has several significant drawbacks: the contact surface of the reacting media is limited, which eliminates the completeness of the chemisorption process; the humidity regime in collective protection facilities is deteriorating, since excess moisture (water vapor) is not removed from the inhabited compartment of the collective protection facility, which reduces the working capacity and worsens the physical and psychological state of the sheltering personnel during prolonged stay in the shelter, and also creates the possibility of getting into the air the environment of the inhabited compartment along with droplets of water of an alkaline solution from the absorber; the principle on which this method is based requires constant replacement of the chemisorbent of an alkaline solution of the elements of the first group, since under certain conditions (when excessive concentrations of carbon dioxide CO _{2 are} fed under conditions of prolonged stay of personnel in the shelter), acid soluble hydrocarbonates are formed in an irreplaceable alkaline solution , which leads to a deterioration in the process of air purification from carbon dioxide.

 The technical result of the proposed method of purification of air from carbon dioxide in the inhabited compartment of the collective defense facility is to increase the efficiency of air purification in confined spaces of collective defense facilities, to create optimal conditions for the work of personnel located in collective defense facilities, without compromising the physical environment.

The technical result is achieved by the fact that air with an increased concentration of carbon dioxide CO ₂ drawn from the inhabited compartment of the protective structure is passed through a weak alkaline solution of the elements of the second group with the addition of crystallizers to prevent the formation of acidic soluble salts of hydrocarbons, and then passed through a metallized charge located above the alkaline solution , delaying alkali droplets carried out by the air pressure from the solution and binding the carbon dioxide that failed to react be in solution. The binding reaction of carbon dioxide is carried out with the release of a precipitate of insoluble salts (carbonates). The air passed through a weak alkaline solution of the elements of the second group with a crystallizer and a metallized charge (copper chips) is dried and cooled to remove water vapor and droplets of an alkaline solution not retained by the charge, and then fed to the inhabited compartment of the collective protection object.

Thus, the distinguishing features of the invention:
a) a chemical reaction of binding carbon dioxide with an alkaline solution of elements of the second group (for example, calcium) is carried out in the presence of a crystallizer of solid particles of carbonates, preventing the formation of acidic soluble salts;
b) on alkaline solution to increase the surface area of contact of phases a metallised charge (copper shavings) which bind neuspevshuyu react carbon dioxide CO ₂ solution droplets alkali staked into the charge air pressure, passed through the solution;
c) dehumidification and cooling of the air leads not only to an improvement in its physical characteristics (temperature and humidity), but also to the removal of droplets of alkaline solution from the air not retained by the metallized charge.

As a result, the excessive concentration of toxic carbon dioxide CO ₂ is reduced, and the likelihood of dropping alkaline solution droplets into the air at the same time as the physical characteristics (lowering temperature and humidity) of the purified air is eliminated. Consequently, the living conditions of the personnel improve with prolonged stay in the shelter.

Example. Through an alkali solution Ca (OH) ₂ with CaCO ₃ crystallizer added (solid particles of chalk crumb), air taken from the inhabited compartment with a high content of carbon dioxide and excess humidity is passed through bubbler pipes. As a result of the bubbling process, a gas-liquid medium is formed, and the presence of a crystallizer of solid particles of carbonates (for example, chalk chips) prevents the formation of acidic soluble salts - hydrocarbons in solution
CaCO ₃ + H ₂ O + CO ₂ Ca (HCO ₃ ) ₂
as a result, carbon dioxide is in equilibrium with a saturated solution of carbonates. Therefore, in a heterogeneous gas-liquid medium at room temperature, an irreversible chemical reaction occurs with the formation of a precipitate
CO ₂ + Ca (OH) ₂ CaCO ₃ + H ₂ O,
as it accumulates, the precipitate formed settles. The alkali solution of the elements of the second group under the influence of bubbling constantly wets the layer of metallized charge (copper chips) located above the solution. Failing to react in the solution, the molecules of carbon dioxide and droplets of an alkaline solution deposited on the surface of copper chips react with each other (copper chips do not participate in the reaction). At the same time, part of the moisture vapor settles on the metallized charge, condensing.

 The air purified from carbon dioxide is drained (from water vapor and droplets of an alkaline solution not captured by the charge) and cooled, and then fed to the inhabited compartment of the collective defense facility.

Using the proposed invention will allow:
to eliminate the almost completely harmful effect of carbon dioxide on the length of stay in the collective protection facility for personnel in conditions of complete isolation;
increase the efficiency of air purification in the inhabited compartment;
reduce the cost of operating and maintaining air supply systems of the collective protection facility;
reduce the amount of chemisorbent stored in shelters, i.e. no constant replacement of the alkaline solution of the elements of the second group necessary for the carbon dioxide binding reaction will be required;
ensure that the normal temperature and humidity conditions are maintained in the inhabited compartment of the shelter, while preventing droplets of alkaline solution from entering the air of the compartment, thereby increasing the safety of the air purification process;
to ensure the maintenance of the chemical composition of air in the inhabited compartment of the collective protection object for a long period of time within the limits corresponding to the requirements for habitability factors.

Claims (2)

 1. A method of purifying air from carbon dioxide in an inhabited compartment of an object of collective protection by absorbing carbon dioxide with an alkaline solution, cooling purified air and then supplying oxygen-enriched air to the inhabited compartment of an object, characterized in that the absorption of carbon dioxide is carried out with an alkaline solution of elements of the second group in the presence of crystallizer, which is a solid particle of carbonates, while a metallized charge is placed over the surface of the solution to precipitate droplets an alkaline solution barbated with air, which binds the carbon dioxide that failed to react in the solution, and is dried before cooling.  2. The method according to claim 1, characterized in that as the metallized charge using copper chips.